ITUD980021A1 - SCRAP PREHEATING PROCEDURE FOR ELECTRIC ARC OVEN AND RELATED DEVICE - Google Patents

Description

Description of the invention having as title:

"PROCEDURE FOR PREHEATING SCRAP FOR ELECTRIC ARC OVEN AND RELATED DEVICE"

FIELD OF APPLICATION

The present invention relates to a scrap preheating process for electric arc furnaces and the relative device as expressed in the respective main claims. The invention is used in the steel industry for the preheating of scrap with the fumes coming out of said electric furnaces during the melting cycle.

The invention is applied both to electric arc furnaces of the alternating current type and of the direct current type.

STATE OF THE TECHNIQUE

Electric arc furnaces used for the production of steel starting from scrap and recovery materials of various kinds are known in the art.

To obtain energy savings, it is currently known to load the furnace with scrap preheated by the heat of the fumes evacuated from the furnace itself through the fourth hole on the vault, thus allowing to reduce the time required for melting the scrap and therefore to increase the productivity of the furnace. electric.

More specifically, the fumes deriving from the melting process are conveyed, through suitable ducts, into special baskets containing the scrap then used for loading the furnace.

The heat necessary for the preheating of the scrap is obtained both for the temperature of the fumes and for the effect of the chemical reaction of post-combustion of the carbon monoxide (CO) contained in them.

To condition and increase this post-combustion reaction, oxygen and / or air with additives and / or comburent gases are blown into the flue gas evacuation duct.

In order to contain the dimensions of the preparation and loading systems of electric furnaces, and to optimize and speed up the unloading cycles of the scrap in the furnace, the operators in the sector are increasingly moving towards the creation of integrated and compact structures including one or more baskets of preheating associated with automatic handling means able to arrange them in the various cooperation positions with the electric oven according to the phase of the cycle in progress. These solutions have proved to be efficient for some aspects such as, for example, the reduced size, the containment of the opening times of the vault during the loading phase, the reduction of the movements of the baskets, the speed of execution of the operations of loading the baskets and of unloading in the oven and others. In many cases, however, the reduction of the distance between the kiln and the relative loading basket, and therefore the reduction of the fume evacuation section from the kiln to the scrap, has led to the inconvenience of the too short transit time which does not allow an effective and complete chemical afterburning reaction of CO.

Due to this, the fumes reach the unburnt scrap and with poor ability to release thermal energy for adequate preheating.

The completion times of the post-combustion of the CO fumes are also variable according to the type of material that is melted inside the furnace and the type of process in progress and therefore a rigid structure does not allow to effectively cover a range of possible conditions .

The uncontrollability of said post-combustion phenomenon can therefore cause inadequate preheating of the scrap, negatively affecting the subsequent melting cycle of the furnace.

To obviate the drawbacks of the known art and to obtain further advantages, the present applicant has studied, tested and implemented the present invention.

EXPOSURE OF THE FOUND

The present invention is expressed and characterized in the respective main claims.

The secondary claims set out variants to the main solution idea.

The purpose of the present invention is to provide a scrap preheating process for electric arc furnaces which allows the degree of post-combustion of the carbon monoxide (CO) present in the fumes to be controlled and adjusted in a desired manner and therefore to regulate the capacity of the fumes to transfer thermal energy to the scrap.

Another object is to provide a compact and functional device which embodies the aforesaid process, without compromising the productivity of the electric oven to which it is associated.

According to the invention, the fumes coming out from the fourth hole of the electric furnace are conveyed into a basket for containing the scrap located near the furnace.

According to the invention, the length of the evacuation duct, connecting the fourth hole to the basket, is adjusted according to the desired degree of CO afterburning to be obtained.

In one formulation of the invention, said length is set and / or varied during the melting cycle as a function of the material being melted inside the furnace and / or the type of melting process carried out and / or the phase of the cycle itself. According to a variant, said length is also set in relation to the type of material to be preheated.

According to the invention, the adjustment of said length is carried out by providing a smoke evacuation duct having at least one section of variable extension.

In one embodiment, said portion of variable extension is constituted by a telescopic or telescopically associated connection, placed in an intermediate position with the evacuation duct.

According to another variant, said portion of variable extension is constituted by an axially compressible / extensible bellows fitting.

According to yet another variant, said section of variable extension is constituted by a tubular element interchangeable with conjugated tubular elements of different length.

According to a variant, the smoke evacuation duct comprises an external casing consisting of a cooling tube circuit and an internal layer of refractory material.

With the invention, the fumes coming out from the fourth hole in the vault of the furnace take a time proportional to the length of the evacuation duct to reach the basket and the scrap.

This determines the occurrence of a more or less complete post-combustion of the CO and therefore the development of a greater or lesser thermal energy to be transferred to the scrap. The regulation of the thermal energy developed allows to obtain a control of the temperature of the fumes entering the basket and therefore to achieve an optimal preheating of the scrap contained in it to the advantage of the subsequent melting phase.

According to a variant of the invention, in order to further condition said post-combustion of the CO, means are provided for blowing in adjuvant agents, such as for example hot air, oxygen, additivated air, gases or comburent mixtures, in cooperation with the smoke evacuation duct. In this case, the length of the evacuation duct is also defined as a function of said inputs of adjuvant agents.

ILLUSTRATION OF DRAWINGS

The attached figures are provided by way of non-limiting example and illustrate a preferential solution of the invention.

In the tables we have that:

- fig. la schematically illustrates the scrap pre-heating device according to the invention in a first operative position;

- fig. 1b shows the device of fig. the in a different operating position;

- fig. 2 is an axonometric view of a variant of the device of figs. la, lb.

DESCRIPTION OF THE DRAWINGS

With reference to the attached figures, the number 10 generally indicates the device according to the invention for preheating scrap 11 to be fed to the electric arc furnace 12.

Said device 10 comprises a smoke evacuation duct 13 connected to the fourth hole 14 present on the vault 15 of the electric furnace 12 and connected to the basket 16 for containing scrap 11. Said evacuation duct 13 is associated with the fourth hole 14 by means of an element a chimney 17 integral with vault 15 and has a branch 18, visible only in fig. 2, arranged in an intermediate section between said fourth hole 14 and basket 16. Through said branch 18, connected to evacuation means, the fumes of the furnace 12 are evacuated when the basket 16 is in a different condition from that of preheating the scrap 11 .

The basket 16 substantially comprises a containment body 16a, with a capacity conjugated to the quantity of scrap 11 necessary to feed the kiln 12, closed at the top by a removable lid 16b. In correspondence with its bottom 16c, said basket 16 has valve elements 19 that can be opened for discharging the scrap 11 inside the furnace 12, said bottom 16c also cooperating with a smoke transit chamber (not shown) which can also have the function of sedimentation and post-combustion chamber.

The basket 16 is, in the present case, associated with a mobile carriage 22 sliding on a track 21 extending from a parking position of the basket 16, lateral and in proximity of the oven 12, up to above said oven 12.

The smoke evacuation duct 13 comprises a main section 23 of fixed extension, in this case shaped like an elbow, to which a variable extension section 20 is associated.

In the present case, the variable extension section 20 is terminally associated with the main section 23 and is connected to a tubular extension 116b cooperating with a smoke inlet opening obtained in the cover 16b and defining the mouth 24 of the basket 16.

In the solution of Figs. la, 1b, the variable extension portion 20 consists of a connecting element 25 telescopically associated with the main portion 23, so as to be able to slide externally and coaxially to the end portion 23a thereof. This sliding of the connecting element 25 determines the variation of the total length of the evacuation duct 13.

In the present case, since the end portion 23a is substantially horizontal, the variation in the length of the evacuation duct 13 defines the variation in the distance between the fourth hole 14 and the inlet 24 of the basket 16, in this case from a value "d1 "to a" d2 "value lower than" d1 ".

According to a variant not shown, said connecting element 25 in turn has a telescopic structure comprising a plurality of stages coaxially constrained one within the other.

According to yet another variant, the variable extension portion 20 is constituted by a tubular element with a telescopic structure integral with the main portion 23. According to another variant not shown, the variable extension portion consists of a fitting that can be replaced with fittings of different length.

In the solution illustrated in fig. 2, the variable extension portion consists of an axially compressible / extensible bellows fitting 26. In the present case, said bellows fitting 26 is in a condition of minimum extension.

In the illustrated solution, the evacuation duct 13 comprises an external casing consisting of a tube circuit 27 for cooling and an internal layer 28 made of refractory material.

In the present case, the tubes of the tube circuit 27 are arranged transversely to the direction of advance of the fumes.

According to a variant, said pipes are arranged longitudinally to the direction of advance of the fumes. According to another variant, the tube circuit 27 comprises two or more layers of tubes arranged one in front of the other.

The procedure for preheating the scrap 11 by means of the device 10 provides that the fumes emerging from the fourth hole 14 are conveyed into the basket 12 after having moved the variable extension portion 20 for setting the desired length of the evacuation duct 13.

The basket 16 adjusts its position in relation to this variable length by moving, in association with the mobile carriage 22, on the track 21 towards / away from / to the oven 12.

The overall length of the evacuation duct 13 is modulated in relation to the temperature of the fumes required at the mouth 24 of the basket 16 for the desired degree of preheating of the scrap 11.

With the same conditions of the melting process, in fact, by increasing this length, a greater completion of the CO post-combustion reaction is obtained and therefore a corresponding development of heat which raises the temperature of the fumes entering the basket 16.

Figs. la, 1b show two possible configurations of the preheating device 10, one (fig. la) with a shorter length of the portion between the furnace 12 and the scrap 11 and the other with a greater length. The choice of the length of the evacuation duct 13 is therefore made in relation to the need to obtain a greater or lesser degree of post-combustion of the CO.

Since the quantity of CO present in the fumes depends on the material that is melted inside the furnace 12, or on the type of melting process adopted, said length of the evacuation duct 13 can be correlated to these parameters. Said length can also be modulated in relation to the type and / or consistency and / or condition of the scrap 11 present inside the basket 16.

According to a variant, schematically illustrated in figs. la, 1b, the post-combustion of the CO is conditioned by blowing in adjuvant substances, for example hot air, oxygen, gas or combustive mixtures, by means of injectors or burners 29 associated with the evacuation duct 13.

In this solution, the overall length of the evacuation duct 13 is also determined as a function of the nature of said adjuvant substances and their quantity blown.

In this case, said injectors or burners 29 are arranged only in correspondence with an intermediate portion of the main section 23 of the evacuation duct 13.

According to a variant not shown, said injectors or burners 29 are associated near the mouth 24 of the basket 16.

According to another variant not shown, the modification of the length of the duct between the fourth hole 14 and the basket 16 is subject to the measurements of a fume analyzer suitable for determining the level of combustion and / or the composition of the fumes passing through the duct. 13.

Claims (1)

CLAIMS 1 - Scrap preheating procedure (11) for electric arc furnaces (12), whether they are AC or DC type, said procedure providing for the conveyance, through an evacuation duct, of the fumes coming out from the fourth hole (14) present on the vault (15) of the kiln (12) inside a basket (16) for containing scrap (11) to be preheated, said basket being associated with handling means, characterized in that it provides for the adjustment of the travel section of the fumes from the kiln (12) to scrap (11) according to the desired degree of completion of the post-combustion reaction of the carbon monoxide (CO) present in the preheating fumes. 2 - Process as in Claim 1, characterized in that the adjustment of the traverse of the fumes is carried out according to the type of melting material of the furnace (12). 3 - Process as claimed in Claim 1 or 2, characterized in that the adjustment of the traverse of the fumes is carried out according to the type of melting process of the furnace (12). 4 - Process as in one or the other of the preceding claims, characterized in that the adjustment of the traverse of the fumes is performed according to the nature and / or consistency and / or condition of the scrap (11) to be preheated. 5 - Process according to one or the other of the preceding claims, characterized in that it provides for the blowing in of CO post-combustion accelerating agents in the traverse of the fumes from the furnace (12) to the basket (16). 6 - Process according to Claim 5, characterized in that the adjuvant agents consist of hot air and / or oxygen and / or gas and / or combustive mixtures. 1 - Scrap preheating device (11) for electric arc furnaces (12), whether of AC or DC type, said device comprising at least one scrap containment basket (11) associated with handling means and arranged in proximity of the furnace (12), said basket being connected to the fourth hole (14) present on the vault (15) of the furnace (12) by means of a smoke evacuation duct, characterized in that the evacuation duct (13) comprises at least one section of variable extension (20) for adjusting the overall section of travel of the fumes from the furnace (12) to the basket (16) functionally to obtain a desired degree of completion of the post-combustion reaction of the CO present in said fumes. 8 - Device as claimed in Claim 7, characterized in that the variable extension section (20) consists of a connecting element (25) telescopically associated with a section (23) of the evacuation duct (13). 9 - Device as claimed in Claim 7, characterized in that the section of variable extension (20) is a telescopic element. 10 - Device as claimed in Claim 7, characterized in that the variable extension portion (20) consists of an axially compressible / extensible bellows fitting (26). 11 - Device as per the preceding claims from 7 onwards, characterized in that the variable extension section (20) is replaceable. 12 - Device as per the preceding claims from 7 onwards, characterized in that the evacuation duct (13) comprises, for at least a substantial part of its length, an external tube circuit (27) for cooling internally lined with a layer (28 ) in refractory material. 13 - Device as per the preceding claims from 7 onwards, characterized in that the evacuation duct (13) has, in an intermediate section, an alternative branch (18) for conveying fumes to evacuation means. 14 - Device as per the preceding claims from 7 onwards, characterized in that the evacuation duct (13) has injector and / or burner means (29) for blowing in fumes conditioning agents. 15 - Device according to the preceding claims from 7 onwards, characterized in that in the evacuation duct (13) there is a fume analyzer which serves to adjust the length of said duct (13). 16 - Process as in claims 1 to 6 and device as in claims 7 to 15, characterized in that they adopt the contents of the description and drawings.